A detaching method of sheets from a stack of sheets from a stack of sheets and a relative detaching apparatus is disclosed, including at least a gripping head of a handling device of sheets and a nozzle assembly apt to eject an air flow to a lateral edge of a stack of sheets, furthermore including: a storage assembly of pressurised air provided at least with a compressed-air tank equipped with a pressure multiplier and a relative first pressure adjuster; and a high-pressure pipe between the nozzle assembly and the storage assembly intercepted by a fast-opening electrovalve. The nozzle assembly is provided with a nozzle, supplied through the electrovalve, configured as a convergent/divergent spout.

An uncoiling, blanking and forming method includes the steps of: 1) uncoiling a steel coil, wherein a steel strip uncoiled from the steel coil is cleaned and straightened and is fed by a pinch roller to a blanking region; 2) laser blanking, wherein the steel coil enters the blanking region, is cut by a laser cutting head by way of laser blanking to form sheets with a required shape, with waste materials falling down and being conveyed to the outside; 3) outputting the sheets, wherein the sheets pass over a magnetic telescopic belt conveyor, and then carried by means of a manipulator or a robot to a stamping process; 4) stamping forming, wherein the sheets are stamped to form workpieces; and 5) checking, wherein the workpieces are checked and put in storage. The present invention can achieve joining-up in series of a blanking line and a stamping forming line and realize matching therebetween, and can reduce intermediate steps such as stacking, packing, transportation, positioning, unpacking, carrying, and centring of sheets and stamping-formed workpieces, and also can reduce the room required for transfer, simplify the work flow and joins up procedures in series, to directly machine a material coil by laser blanking to form formed parts.

An uncoiling, blanking and forming method includes the steps of: 1) uncoiling a steel coil, wherein a steel strip uncoiled from the steel coil is cleaned and straightened and is fed by a pinch roller to a blanking region; 2) laser blanking, wherein the steel coil enters the blanking region, is cut by a laser cutting head by way of laser blanking to form sheets with a required shape, with waste materials falling down and being conveyed to the outside; 3) outputting the sheets, wherein the sheets pass over a magnetic telescopic belt conveyor, and then carried by means of a manipulator or a robot to a stamping process; 4) stamping forming, wherein the sheets are stamped to form workpieces; and 5) checking, wherein the workpieces are checked and put in storage. The present invention can achieve joining-up in series of a blanking line and a stamping forming line and realize matching therebetween, and can reduce intermediate steps such as stacking, packing, transportation, positioning, unpacking, carrying, and centring of sheets and stamping-formed workpieces, and also can reduce the room required for transfer, simplify the work flow and joins up procedures in series, to directly machine a material coil by laser blanking to form formed parts.

What is disclosed is a robot gripper having a receiving area which is configured to be connected to an industrial robot, and having at least one suction unit which is configured to be connected to a vacuum source. The suction unit comprises a suction surface on which a preferably plate-shaped workpiece, which preferably consists at least in sections of wood, wood materials, plastic, aluminum or the like, can be held by means of negative pressure. The suction unit comprises a substantially straight pressing edge in an edge section. The robot gripper further comprises an actuator configured to tilt the suction unit about a first tilt axis relative to the receiving area.

What is disclosed is a robot gripper having a receiving area which is configured to be connected to an industrial robot, and having at least one suction unit which is configured to be connected to a vacuum source. The suction unit comprises a suction surface on which a preferably plate-shaped workpiece, which preferably consists at least in sections of wood, wood materials, plastic, aluminum or the like, can be held by means of negative pressure. The suction unit comprises a substantially straight pressing edge in an edge section. The robot gripper further comprises an actuator configured to tilt the suction unit about a first tilt axis relative to the receiving area.

A loading and unloading device for a machine, a machine for machining panel-like workpieces, and a workpiece support for such a machine and a method for loading and unloading such a machine, having a loading and unloading module, wherein the loading and unloading module has a vertically upwardly oriented raising device for lifting a cut-free workpiece part and a vertically downwardly oriented gripping device (38) for holding an unmachined, panel-like workpiece.

A loading and unloading device for a machine, a machine for machining panel-like workpieces, and a workpiece support for such a machine and a method for loading and unloading such a machine, having a loading and unloading module, wherein the loading and unloading module has a vertically upwardly oriented raising device for lifting a cut-free workpiece part and a vertically downwardly oriented gripping device (38) for holding an unmachined, panel-like workpiece.

A method configures a workpiece-related workpiece holding device for press automation. At least one workpiece-specific holding element of the workpiece holding device is configurably secured to a support of the workpiece holding device in at least one degree of configuration freedom. The method has the steps of (a) imaging a real image of the at least one workpiece-specific holding element on a display device and (b) outputting configuration information relating to the at least one workpiece-specific holding element on the display device, the configuration information including at least one piece of reference information relating to a relative reference orientation and/or a relative reference position of at least one region of a workpiece-specific holding element relative to the support.

A method configures a workpiece-related workpiece holding device for press automation. At least one workpiece-specific holding element of the workpiece holding device is configurably secured to a support of the workpiece holding device in at least one degree of configuration freedom. The method has the steps of (a) imaging a real image of the at least one workpiece-specific holding element on a display device and (b) outputting configuration information relating to the at least one workpiece-specific holding element on the display device, the configuration information including at least one piece of reference information relating to a relative reference orientation and/or a relative reference position of at least one region of a workpiece-specific holding element relative to the support.

Tooling (100) for picking up two-dimensional workpieces comprises a main body (110) and a plurality of holding elements (131, 132) arranged on the main body (110), wherein the holding elements (131, 132) are movable relative to the main body (110) independently of one another. Each of the holding elements (131, 132) is fastened in an end region of an arm (121.1 . . . 10, 122.1 . . . 10). The arms (121, 122) are movable passively relative to the main body (110) along a linear movement path in a longitudinal extension of each particular arm (121, 122). The tooling (100) comprises, for each of the arms (121, 122) a fixing apparatus, by means of which a position of each particular arm (121, 122) along the movement path is fixable. On account of its passive character, the tooling (100) according to the invention is lightweight and can be produced cost-effectively. Compared with fixedly configured tooling, reduced costs arise on account of the configurability, because different types of tooling do not have to be kept available and provided. The storage area for replacement tooling is saved, and also an automatic tooling changing station or a manual tooling change become superfluous. As a result of the geometry according to the invention, the tooling (100) can be set easily, no complex movements and accordingly no complicated setting devices (for example multiaxial robots) are necessary.